DeltaV SIS with Electronic Marshalling - Emerson

DeltaV SIS Process Safety System

Product Data Sheet October 2017

DeltaV Safety Instrumented System (SIS)™ with Electronic Marshalling Optimized process reliability Simplified safety lifecycle management Flexibility to meet project needs I/O anywhere you need it Reduces installed cost of system Field mounted capable hardware

Introduction The DeltaV SIS™ process safety system has a uniquely scalable modular architecture that is based on the CHARMs Smart Logic Solver (CSLS) and the unprecedented flexibility and ease of use of the Emerson Electronic Marshalling solution. Each CSLS provides I/O processing, Safety Integrity Level 3-capable logic solving, and diagnostics in a single logic solver. The CSLS supports up to 96 individually configurable channels, allowing flexibility for implementing safety instrumented functions and is designed specifically for multi-core home run cables or field junction box installation. All communications are completely redundant from the channel (LS CHARM) to the CSLS. Integrated HART® I/O brings field diagnostics into the CSLS.

Benefits Optimized process reliability: Emerson has extended DeltaV Electronic Marshalling technology to safety instrumented systems, with DeltaV SIS being a key component of the Smart SIS Solution. Research shows that more than 90% of all faults in SIS applications occur in field instruments and final elements. The DeltaV SIS process safety system has the world’s first Smart Logic Solver using LS CHARMs. It communicates with intelligent field devices using the HART protocol to diagnose faults before they cause spurious trips. This approach increases process availability and reduces lifecycle costs.

The DeltaV SIS™ process safety system has the world’s first CHARMs Smart SIS Logic Solver, using the power of predictive intelligence to increase the availability of the entire safety instrumented function in combination with the advantages of the Emerson Electronic Marshalling solution. Flexibility to meet project needs: Whether you have an isolated wellhead or a large emergency shutdown (ESD) application, the DeltaV SIS system scales to provide you with the safety coverage you need for your SIL 1, 2 and 3 safety functions. Each CHARMs Smart Logic Solver provides I/O processing, SIL 3-capable logic solving, and diagnostics. This means that processing power is added as the system expands, and no additional processors will ever be required. Scan rate and memory usage are constant and independent of system size.

DeltaV SIS with Electronic Marshalling Modularity also provides isolation of safety instrumented functions (SIF). This isolation eliminates single-points of failure for improved availability and safety integrity. The DeltaV SIS system looks for new hardware every scan, so equipment can be added to a running system in real time. Online addition of new logic solvers will not interrupt your process. Simplified safety lifecycle management: The DeltaV SIS CSLSs are SIL 3-rated for both simplex and redundant architectures. Redundant CSLS pairs can be installed for increased process availability of your SIFs. I/O anywhere you need it: The DeltaV SIS CSLS provides an unprecedented flexibility in safety system I/O topology. Using standard Ethernet infrastructure hardware you can add safety related I/O anywhere you need it. From a local I/O cabinet to remote enclosures miles away, simply install the CSLS and connect it to the Local Safety Network (LSN). Each CSLS can read the input signals from any other CSLS on the same LSN every 50 ms, the same as the inputs wired directly to its own LS CHARM system. Reduces installed cost of system: DeltaV SIS Electronic Marshalling helps reduce overall system costs by eliminating internal cabinet cross wiring, reducing overall footprint, simplifying SIF design, and reducing Factory Acceptance Test (FAT) activities. Electronic Marshalling provides separation between I&E hardware installation schedules and SIF development. Wiring can begin earlier knowing any late changes can be done without lifting a wire. The ability to read any input on the LSN allows more efficient cabinet designs and accommodates late scope changes to add I/O anywhere. Adding additional SIF capacity does not require re-wiring I/O. Simply read the I/O signals from the proper CSLS, without lifting a wire. Fully redundant communications: The CSLS architecture is fully redundant. It starts with the two logic solvers on a carrier. The carrier has redundant Safety Network Ports (SNP) for communication with primary and secondary LSN connections. There are two 24 VDC input power connections. The carrier connects to the CHARMs base plates providing redundant power and communication buses to the LS CHARMs. If required for availability you have the option to use redundant output LS CHARM Terminal Blocks with or without internal 1 A relays for both DTA and ETA service. Everything is redundant down to the individual channel.

www.emerson.com/deltavsis

October 2017 Field mounted capable hardware: All components of the CSLS are rated for installation in Class 1/Div 2 or Zone 2 hazardous locations. The extended operating temperature ranges and G3 environment rating allows them to be installed in field mounted junction boxes. This further reduces the footprint required in central equipment rooms, as well as reduces the overall wiring infrastructure of traditional multi-core instrumentation cable. Plug and Play I/O: The DeltaV SIS CSLS has been designed for ease of use, both in physical installation and its software tools. Components snap together with secure DIN-rail latches and interlocking carrier connectors. Attach a series of 96 I/O channels to a DIN-rail in a matter of minutes. Insert the LS CHARMs and auto sense the node to create the I/O definition automatically in your DeltaV SIS configuration database. LS CHARMs use a self keying system to automatically set a channel for a specific LS CHARM type. Users cannot mistakenly insert a LS CHARM into the wrong terminal block. Field power is provided through a redundant 24 VDC bus to each LS CHARM, with up to 100 mA per LS CHARM. Higher current Discrete Input Channels can be powered through integrated power injection bus local to each CHARM base plate. LS Discrete Output terminal blocks with integrated relays are also available for up to 1A continuous load.

Product Description For Use in SIL 3 Applications With a safe failure fraction (SFF) greater than 99%, both simplex and redundant installations of the DeltaV SIS CSLS meet the SIL 3 requirements of IEC 61508 with no restrictions. Redundant CSLSs increase availability, but because both simplex and redundant CSLSs provide hardware fault tolerance and SFF to meet SIL 3 requirements, redundancy does not increase safety.

Safety Instrumented Function (SIF) - Based Approach The DeltaV SIS system design was based on IEC 61511 SIF concept, where every logic solver is a container for a small number of SIFs. Unlike other system architectures, with modular logic solving architecture, the logic solver is no longer a single point of failure for the entire process. If failures were to occur, only the equipment tied to the logic solver would be affected.

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DeltaV SIS with Electronic Marshalling

October 2017

The DeltaV SIS SIF-based approach does not mean that all of the safety logic and I/O have to fit into one logic solver. All input data is made available to every logic solver on the LSN every 50 ms the same as the local inputs on every CSLS.

Both logic solvers in a redundant pair are monitored for integrity alarms at all times, and an integrity error in either CSLS will notify the operator of a failure. Events that can cause integrity alarms include:

With DeltaV SIS logic solvers, neither the scan rate nor the execution of a SIF is altered by changes or additions to another SIF. DeltaV SIS logic solvers always execute deterministically, every 50 ms, regardless of how much I/O is running on the system.

Hardware failure within a logic solver.

Communications failure between a logic solver and the LSN.

Communications failure between a redundant pair of logic solvers.

Removal of a logic solver from the carrier.

Redundancy The redundant logic solvers include two CSLSs installed side-byside on the CSLS Carrier. The CSLS Carrier has redundant power and communication connections to the base plates that are wired to the field devices. Each CSLS of the redundant pair has a separate power supply. No control strategy configuration is required to take advantage of CSLS redundancy because the DeltaV SIS auto-sense capability automatically recognizes the redundant pair of cards. When redundancy is chosen, the two CSLSs run in parallel at all times. Both read the inputs from the I/O terminals, both execute the logic and both drive the outputs at the I/O terminals. There is no concept of primary and backup or master and slave, which is unlike any other safety system. The only difference between the two CSLSs is that one communicates with the engineering and operator workstations as well as the dedicated LSN. This CSLS has the Active light illuminated. The other CSLS is communicating only with the LSN.

Logic Solver Switchover In the event that a failure is detected in one of the CSLSs, the CSLS will automatically go into a failed state. In this condition, there is no impact to the partner CSLS or the physical outputs. The partner CSLS continues to read inputs, execute logic, and drive outputs. The transition from redundant to simplex is completely bumpless.


The health and status of both logic solvers and their channels are available in the Diagnostics Explorer. When one CSLS of a redundant pair of logic solvers is removed online, there is no disturbance to the process. When the missing CSLS is replaced with another, the new CSLS completes its power-up self-tests before the active CSLS cross-loads the current database. In safe areas, failed CSLSs can be replaced under power. In hazardous areas, appropriate installation procedures must be followed.

Online Proof Testing Online proof testing can be performed on a redundant pair of logic solvers. The desired proof-test interval is set in the configuration. The logic solvers perform the proof test automatically, with a warning provided to the operator before the automatic proof test is started.

Diagnostics The DeltaV SIS logic solvers execute extensive self-testing on a continuous basis to detect potential faults. Faults detected by logic solver diagnostics can be associated with the logic solver itself or associated with field devices, field wiring, or other conditions not related to hardware. DeltaV SIS provides standard alarms to annunciate faults detected by logic solvers in the operator interface. No special configuration is required. When a diagnostic alarm occurs, it appears on the alarm banner of the operator interface. The operator is shown the type of alarm (failed, maintenance, etc.), as well as text for the active condition or “multiple conditions” if more than one alert condition is active for the particular alarm.

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DeltaV SIS with Electronic Marshalling Sequence of Events Capability With DeltaV SIS, events are automatically generated as function blocks are executed within a module scan. Events are time stamped with a resolution of <1 ms, and they are recorded in the sequence that they occur in the Event Chronicle. When using standard function blocks such as input blocks, voter blocks, and cause and effect blocks, a standard set of events are automatically generated without special configuration or programing required. For example, I/O failures, trip limits, first outs, and other similar events are automatically time stamped by function blocks and recorded in the Event Chronicle. When a process variable exceeds the trip limit, DeltaV SIS records the event along with the analog value and the trip condition.

October 2017

DeltaV SIS Electronic Marshalling Hardware Includes:

CHARM Smart Logic Solver Carrier (DIN rail mounted and supports a redundant pair of CHARM Smart Logic Solvers, redundant 24 VDC power connectivity, and redundant Ethernet Safety Network communication Ports).

CHARM Smart Logic Solver (provides redundant safety logic processing and communication to up to 96 LS-CHARMs).

CHARM Base plate (DIN rail mounted with interleaving power and bus connectors. Supports 12 LS CHARMS and their terminal blocks, as well as connection for injected field power).

In general, when there is a plant event that triggers an ESD from the SIS, one input will exceed a trip limit on one scan and this will cause outputs to trip and more inputs will then change state. Sequence of Events Recording has been used to find that first input that caused the trip by looking at all of the inputs in the plant. With the DeltaV SIS system, the operator simply filters the Event Chronicle for first-out trips, and the first-out is clearly visible.

LS CHARM Terminal Block (removable terminal block providing terminal connections to field wiring and physical latch for LS-CHARM).

LS CHARMs (Logic Solver Characterization Module for each field signal. Provides basic analog to digital conversion and signal isolation to the redundant communication bus).

Cable Extenders that provide flexibility in carrier mounting.

If higher resolution is required for some channels then they can be wired to both the DeltaV SIS Logic Solver and also to a DeltaV Discrete Input Card for Sequence of Events, which provides a resolution of 0.25 ms.

I/O bus termination (provides bus terminations for redundant I/O bus).

Labeling features for base plate and channel identification.

Integrated HART Integrated HART I/O brings field diagnostics into the logic solver. Field device diagnostics information is not just for pass-through to AMS Device Manager; it is available inside the logic solver. The DeltaV SIS logic solver can also generate HART commands to initiate a partial stroke test in a digital valve controller. The operators can initiate partial stroke tests manually from their operator workstations or they can be scheduled to occur automatically based on the specified test interval. The results from these tests are captured and integrated with the system event history. An alarm can be generated if a partial stroke test fails, alerting maintenance that there is a potential problem with a valve.


The CHARM Smart Logic Solver carrier is mounted to the top of a vertical DIN rail and up to eight CHARM Base plates are mounted below it, snapping easily to the DIN rail as they are connected to each other. The bus termination assembly is attached at the bottom. A standard DIN-rail lock is used to keep the entire assembly in place. A pair of CHARM Smart Logic solvers install on the carrier and communicate over a redundant Ethernet safety network with up to 15 other CSLSs and 1 SZ controller, allowing great flexibility and ease of system expansion. SNPs are available for copper only. SZ controllers connect to both the area control network and the LSN to isolate the CSLSs from the process control system. The SZ controllers has replaceable Ethernet Isolation Ports for connection to both LSN and the DeltaV Area Control network. Starting in DeltaV v14.3 a new Keylock Ethernet Isolation Port, in yellow color plastic, which enable the key inhibit unlock switch on the carrier to allow the key to inhibit the unlock command to all CSLSs on the LSN.

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DeltaV SIS with Electronic Marshalling SZ controllers connect to both the area control network and the LSN to isolate the CSLSs from the process control system. The SZ controllers has replaceable Ethernet Isolation Ports for connection to both LSN and the DeltaV Area Control network. Starting in DeltaV v14.3 a new Keylock Ethernet Isolation Port, in yellow color plastic, which enable the key inhibit unlock switch on the carrier to allow the key to inhibit the unlock command to all CSLSs on the LSN.

October 2017

LS CHARM Types A variety of analog and discrete LS CHARMs are available to meet your specific requirements. The following LS CHARMs are available starting with DeltaV v12.3.1:

LS AI 4-20 mA HART

LS RTD

LS Thermocouple / mV

LS AI 0-10 VDC Isolated

Each baseplate is ordered with 12 terminal blocks: standard terminal blocks or fused, injected power terminal blocks. Electronic Marshalling eliminates the need to partition the I/O wiring to specific channels based on signal type. Simply connect field signal multi-cores in an orderly fashion as desired. Install the appropriate LS CHARM to complete the field circuit and the signal is ready to be used by the CSLS. No cross-wiring required.

LS DI NAMUR

LS DI 24 VDC low-side sense (dry contact)

LS DI 24 VDC Isolated

LS 24 VDC Power

LS DO 24 VDC DTA

Each LS CHARM acts as a circuit protection device and field wiring disconnect. Signals are inherently current limited to protect against wiring faults to ground. Each LS CHARM provides surge protection to meet industry standards in the area of EMC. Under extreme overvoltage conditions due to incorrect field wiring, the LS CHARM will act as a fuse to protect adjacent channels. Signal faults are thus isolated to the single LS CHARM.

LS DO 24 VDC ETA

LS DVC HART DTA

LS DO 24 VDC Redundant DTA

LS DO 24 VDC Redundant ETA

LS DVC HART Redundant DTA

LS DI 120 VAC Isolated

LS CHARMs can be partially ejected to a locked position that disconnects the field wiring from the system to perform field maintenance actions or to remove power to a field device. Activating the LS CHARM latch ejects the LS CHARM to the detent position. Closing the latch locks the LS CHARM in place and isolates the field wiring for field work.

LS DI 120 VAC Isolated Plus


Baseplate extenders and cables provide great flexibility to the LS CHARM installation in existing cabinets or in custom enclosures. Cables are redundant, each carrying 24 VDC field power, 6.3 VDC LS-CHARM power, and one of the communication busses.

Green Solid: Normal Operation

Bus termination provides added robustness for the communication bus and is installed at the end of the physical bus.

Red Solid: Internal Fault detected

Only DeltaV SIS Smart Switches are supported on the Local Safety Network (LAN).

Label features are available to identify channel usage and Baseplate identification to help with maintenance.

All LS CHARMs have a bi-color Power/Integrity LED that indicates the health of the LS CHARM. The indications provide clear, actionable instruction to the maintenance personnel.

Green Blink: Normal awaiting configuration Red Blink: Fault detected on wiring

Discrete LS CHARMs have a Yellow LED to indicate the state of the field signal. (On = circuit is energized) All LS CHARMs meet ISA 71.04-1985 severity level G3 (harsh) corrosion specifications.

LS CHARMs can be added to any existing base plate position and autosensed online. Additional CSLS can be added online.


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DeltaV SIS with Electronic Marshalling I/O Terminal Block Options There are 11 different I/O terminal blocks available to meet the wiring needs of field signals.

Standard Terminal Block

Fused Injected Power Terminal Block

3-wire DI Fused Injected Power Terminal Block

Thermocouple / mV Terminal Block

3-wire AI Fused Injected Power Terminal Block

LS DVC Terminal Block

LS Redundant Terminal Block

LS Redundant DTA Fused Injected Power Relay Terminal Block

LS Redundant DTA Relay Terminal Block

LS Redundant ETA Relay Terminal Block

LS Redundant DVC Terminal Block

The Standard Terminal Block can be used with all LS AI, DI, and RTD CHARM types. For traditional wiring of field instrumentation, the LS CHARMs provide loop power through the internally distributed 24 VDC field power. Refer to specific LS CHARM specifications for wiring information. The Fused Injected Power Terminal block, the 3-wire DI Fused Injected Power Terminal block, and the 3-wire AI Fused Injected Power Terminal block include a 2A field replaceable fuse. The 3-wire DI Fused Injected Power Terminal block is designed to be used with all Isolated discrete Input CHARM types, the 3-wire AI Fused Injected Power is used with the LS AI 4-20mA HART CHARM type, and the Fused Injected Power Terminal block is designed to work with the LS 24 VDC Power CHARM, creating a system-powered circuit that can deliver up to 1 amp (DC) to the field. Each baseplate has a local power bus that can be connected to 24 VDC or 120/230 VAC through the injected power input terminals, located on the Address Plug terminal block. Fused Injected power Terminal Blocks connect to this power bus to provide system power to the field circuit through the isolated LS CHARM. You can combine isolated and system powered circuits on the same baseplate; however, all system powered channels on a baseplate share the same power source.


October 2017 The Thermocouple / mV Terminal Block is specially designed for the usage with the LS Thermocouple / mV CHARM. The Thermocouple / mV Terminal Block has fixed key positions to prevent a mismatch in the field and can only be ordered as an assembly with the LS Thermocouple / mV CHARM. The 3-wire AI Fused Injected Power Terminal Block is designed for 3 wire analog transmitters and can be used with the LS AI 4-20mA HART CHARM. The field power is supplied from the injected power bus on the baseplate, but the power is not removed from the field device when the AI CHARM is removed from the baseplate. There is a Green LED on the terminal block that is lit when power is supplied to the field and the 2A fuse also functions as a means to disconnect power from the field device. Although this terminal block was introduced in 2017, it is backwards compatible to any version of DeltaV SIS with Electronic Marshalling. The LS DVC Terminal Block can be used with the LS DVC HART DTA CHARM type. Refer to specific LS CHARM specifications for wiring information. The LS Redundant Terminal Block can be used with the Redundant DVC Output LS CHARM type. Refer to specific LS CHARM specifications for wiring information. The LS Redundant DTA Fused Injected Power Terminal Blocks are designed for high output current applications and requires the LS DO 24 VDC Redundant DTA or ETA CHARM to drive the relay coil. The Redundant Relay Output Term blocks provide a normally open and normally closed contact with the following ratings:

28.8 VDC at 1 A switching current

48 VDC at 0.4 A switching current

125 VDC at 0.2A switching current

250 VAC at 1 A switching current

The LS Redundant DTA Relay Terminal Block can be used with the LS DO Redundant DTA CHARM type. Refer to specific LS CHARM specifications for wiring information. The LS Redundant ETA Relay Terminal Block can be used with the LS DO Redundant ETA CHARMs type. Refer to specific LS CHARM specifications for wiring information.

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October 2017

The LS Redundant DVC Terminal Block can be used with the LS DVC HART Redundant DTA CHARM Refer to specific LS CHARM specifications for wiring information type.

The keying mechanism consists of two keying posts that rotate and lock into the terminal block base. Each LS CHARM type is assigned a unique key setting.

Although any signal type can be installed in any location on the CHARM baseplates, it is recommended that AC voltage circuits be separated from low voltage signals to comply with safety recommendations and to mitigate induced noise in the signals. Standard Terminal blocks, Fused Injected Power terminal blocks, and LS Redundant DTA Fused Injected Power Terminal Blocks can be used on the same carrier, typically to allow the use of DO 24 VDC isolated CHARMs on higher wattage devices alongside of standard 24 VDC instrumentation signals or Relay contacts.

The LS DVC Terminal Block, LS Redundant DTA Relay Terminal Block, LS Redundant ETA Relay Terminal Block, and the LS Redundant DVC Terminal Block have fixed key positions to prevent a mismatch in the field.

LS CHARM Keying Posts The Terminal Blocks contain keying posts that are automatically set and locked to the unique position of the installed LS CHARM. The keys prevent the insertion of an incorrect LS CHARM during maintenance activities. They are shipped in a neutral position and are set when a LS CHARM is inserted. If needed, the keys can be manually reset to allow a channel to be re-tasked for a different signal type.

LS CHARM Standard Terminal Block.


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October 2017

DeltaV SIS CSLS Capacities Item

Limit

Maximum number of CSLSs on a single SZ Controller

16

Maximum number of Remote I/O Nodes (CIOCs and/or WIOCs) reporting to a single SZ Controller

4

Maximum number of secure parameters per CSLS

96

Maximum number of CSLS I/O channels on a single SZ Controller: 96 CHARMs I/O channels × 16 CSLSs

1536

Maximum number of CSLSs in a single DeltaV SIS system: 100 SZ controllers × 16 CSLSs per SZ controller

1600

Hardware Specifications Common Environmental Specifications (all components) Operating Temperature*

-40 to 70°C (-40 to 158°F)

Storage Temperature

-40 to 85°C (-40 to 185°F)

Relative Humidity

5 to 95% , non-condensing

Protection Rating

IP 20

Airborne Contaminants

ISA-S71.04-1985 Airborne Contaminants Class G3 Conformal coating

Shock

10 g ½-sine wave for 11 ms

Vibration

1mm Peak-to-Peak from 2 to 13.2 Hz; 0.7g from 13.2 to 150 Hz

*Operating any electronics at the higher end of its temperature range for long periods of time will shorten its expected lifetime, see Effects of Heat and Airflow Inside an Enclosure White Paper for more information.


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October 2017

SZ Controller shown on SZ Controller Carrier.

SZ Controller Ethernet Isolation Port or Keylock Ethernet Isolation Port.


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October 2017

SZ Controller shown on Dual Universal Safety Carrier.

CSLS shown on CSLS Carrier.


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October 2017

CSLS Safety Network Port.

CHARM Baseplate with CHARMs Terminal Blocks.


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CHARM Baseplate Terminator Top.

CHARM Baseplate Terminator Bottom.

CHARM Baseplate Extender Top.

CHARM Baseplate Extender Bottom.


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Input LS CHARMs.

Output LS CHARMs.


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October 2017

CHARM Standard Terminal Block.

CHARM 3-wire DI Fused Injected Power Terminal Block.


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CHARM Fused Injected Power Terminal Block.

CHARM Thermocouple / mV Terminal Block.

CHARM 3-wire AI Fused Injected Power Terminal Block.


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LS CHARM DVC Terminal Block.

LS CHARM Redundant Terminal Block.

LS CHARM Redundant DTA Fused Injected Power Relay Terminal Block.


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LS CHARM Redundant DTA Relay Terminal Block.

LS CHARM Redundant ETA Relay Terminal Block.

LS CHARM Redundant DVC Terminal Block.


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October 2017

SZ Controller Hardware Specifications for SZ Controller and Dual Universal Safety Carrier Capacity

One (simplex) or two (redundant) SZ Controllers

Input Power

+24 VDC ±10% at 1 A maximum

Battery Power

+5.0 to +12.6 VDC at 30 uA typical

Redundant Ethernet Connections through Replaceable Ethernet Isolation Ports (EIPs) or Keylock Ethernet Isolation Ports

Copper twisted pair: 10/100BASE-TX with RJ45 connectors; Full duplex operation – 100 m distance

SZ Controller Carrier Mounting

DIN rail latch to vertically oriented T-type rail

Dual Universal Safety Carrier Mounting

DIN rail latch to horizontally oriented T-type rail

Specifications for SZ Controller Number of SZs per System

100

Input Power

+24 VDC ± 10% at 325 mA maximum for simplex; 575 mA maximum for redundant

Heat Dissipation (Redundant)

7 Watts maximum for simplex; 13 Watts maximum for redundant

Fuse Protection (Internal)

Internal non-replaceable fuse

Mounting

One or two slots on the SZ Controller or Dual Universal Safety Carrier

Communication

Redundant Ethernet connections through SZ Controller or Dual Universal Safety Carrier to the: a) Local Safety Network (LSN) b) Area Control Network (ACN) or Modbus TCP ports

LSN, ACN Network Addressing

Auto Assigned during commissioning

Modbus TCP Addressing

Manual, Slave only

DST Limit

1536 for SIS and 384 from CIOCs and/or WIOCs*

Max Data Values Sent

4000/second

Max Data Values Received

500/second

Max Unsolicited Client Nodes

120

BPCS Module Execution Rates

100ms, 200ms, 500ms, 1s, 2s, 5s, 10s, 30s, 60s

LED Indicators Green – Power

Indicates DC power is applied

Red – Error

Indicates an error condition

Green – Active/Standby

Indicates operating mode of each SZ

Yellow flashing – Pri./Sec. CN

Indicates valid control network communication

* Up to 4 WIOCs, CIOCs, Zone 1 Remote I/O nodes and Zone 2 Remote I/O nodes can be assigned to an SZ controller.


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October 2017

CSLS Hardware Specifications for CSLS Carrier Capacity

One (simplex) or two (redundant) CSLS and one (simplex) or two (redundant) Power Modules

Input Power (Redundant)

+24 VDC ± 10% at 12.5 A maximum

Output Power to SIS CHARMs

+24 VDC ± 10% at 10 A maximum +6.3 VDC at 4 A maximum

Redundant Ethernet Connections through Replaceable Safety Network Ports (SNP)

Copper twisted pair: 10/100BASE-TX with RJ45 connectors;

Mounting

DIN rail latch to vertical orientated T-type rail

Full duplex operation - 100 m distance

Specifications for CSLS Number of I/O Channels

96 Channels, Individually defined signal types*

Number of CSLSs per SZ Controller

16

Number of CSLSs per System

1600

I/O update rates

50ms

Power Requirement of CSLS

+24 VDC ± 10% at 325 mA maximum for simplex; 575 mA maximum for redundant (CHARMs are additional)

Power Requirement of Power Modules

+24 VDC ± 10% at 1.5 A maximum simplex and redundant

Power Modules Output to LS-CHARMs

+6.3 VDC ± 3% at 4 A maximum

Heat Dissipation per Carrier with Redundant CSLS pair

18 Watts maximum, which includes: –– –– ––

13 Watts for redundant CSLS (7 Watts for simplex) 3 Watts for redundant Power Modules 1 Watt per Safety Network Port

Fuse Protection (Internal)

Internal non-replaceable fuse

Mounting

One or two slots on the CSLS Carrier

Communication

Redundant Ethernet connections through CSLS Carrier to the LSN

Network Addressing

Auto Assigned during commissioning

LED Indicators Green – Power

Indicates DC power is applied

Red – Error

Indicates an error condition

Green – Active/Standby

Indicates operating mode of each CSLS

Yellow flashing – Pri./Sec. CN

Indicates valid control network communication

* Only 48 of the 96 LS CHARM slots can be configured as output LS CHARMs.


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October 2017

CHARMs Baseplate Hardware Specifications for CHARMs Baseplate Number of Channels per Baseplate

12

Number of baseplates per CSLS

8

Addressing

One Address Plug (1 through 8)

Terminal Blocks

Standard Terminal Block 3-wire DI Fused Injected Power Terminal Block 3-wire AI Fused Injected Power Terminal Block Fused Injected Power Terminal Block Thermocouple / mV Terminal Block LS DVC Terminal Block LS Redundant Terminal Block LS Redundant DTA Fused Injected Power Relay Terminal Block LS Redundant DTA Relay Terminal Block LS Redundant ETA Relay Terminal Block LS Redundant DVC Terminal Block

Shield Connections

1 Screw Cage terminal per channel, plus 1 for cable shield 0.32 – 2.5 mm 2 / 22 – 14 AWG Gold plated connectors for shield continuity

Wire Strip Length

7 - 9 mm / 0.28 – 0.36 in.

Mounting

DIN rail Latch to T-type rail

Specifications for Baseplate Termination, Top and Bottom Shield Connections

2 Screw Cage Terminals 0.32 – 2.5 mm 2 / 22 - 14 AWG

Wire Strip Length

7 - 9 mm / 0.28 – 0.36 in.

Specifications for Baseplate Extenders, Top and Bottom Primary Bus Connection

9-pin D-shell, Primary RS-485 communications bus Primary 24 VDC field power Primary CHARM power

Secondary Bus Connection

9-pin D-shell, Secondary RS-485 communications bus Secondary 24 VDC field power Secondary CHARM power

Specifications for Extender Cables Maximum Bus Length (Including Base Plates)

5.5 m (18 ft)

Available Cable Lengths

2 m, 1 m, 0.5 m (6.7 ft, 3.3 ft, 1.6 ft )


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October 2017

Specifications for Standard Terminal Block Number of Connections

4 Screw Cage terminals 0.32 – 2.5 mm 2 / 22 – 14 AWG

Wire Strip Length

7 - 9 mm / 0.28 – 0.36 in.

Maximum Current

2 A max. at 250 VAC max. *

Color

Black

Specifications for 3-wire DI Fused Injected Power Terminal Block Number of Connections


Wire Strip Length

7 - 9 mm / 0.28 – 0.36 in.

Maximum Current


Field Replaceable Fuse

2A

Color

Black

Specifications for 3-wire AI Fused Injected Power Terminal Block Number of Connections

3 Screw Cage terminals 0.32 – 2.5 mm2 / 22 – 14 AWG

Strip Length

7 - 9 mm / 0.28 – 0.36 in

Maximum Current

30mA max. at 30V DC max. (screw terminal #2) 1 A max. at 30V DC max. (screw terminals #3 and #4)*


2A

Color

Black

LED Indicator

Green – Power going to field

Number of Connections Number of Connections


Wire Strip Length

7 - 9 mm / 0.28 – 0.36 in.

Maximum Current



2A

Color

Black

Specifications for Thermocouple / mV Terminal Block Number of Connections


Wire strip Length

7 - 9 mm / 0.28 – 0.36 in.

Color

Black

Specifications for LS DVC Terminal Block Number of Connections


Wire Strip Length

7 - 9 mm / 0.28 – 0.36 in.

Maximum Current

30 mA max. at 30 VDC max. *

Color

Black


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October 2017

Specifications for LS Redundant Terminal Block Number of Connections


Wire Strip Length

7 - 9 mm / 0.28 – 0.36 in.

Maximum Current


Color

Black

Specifications for LS Redundant DTA Fused Injected Power Relay Terminal Block Number of Connections


Wire Strip Length

7 - 9 mm / 0.28 – 0.36 in.

Maximum Current

1 A at 28.8 VDC / 0.4 A at 48 VDC / 1 A at 250 VAC

Field replaceable Fuse

2A

Color

Black

Specifications for LS Redundant DTA Relay Terminal Block Number of Connections


Wire Strip Length

7 - 9 mm / 0.28 – 0.36 in.

Maximum Current



2A

Color

Black

Specifications for LS Redundant ETA Relay Terminal Block Number of Connections


Wire Strip Length

7 - 9 mm / 0.28 – 0.36 in.

Maximum Current



2A

Color

Black

Specifications for LS Redundant DVC Terminal Block Number of Connections


Wire Strip Length

7 - 9 mm / 0.28 – 0.36 in.

Maximum Current

60 mA max. at 30 VDC max. *

Color

Black


22


October 2017

Specifications for Address Plug Terminal Block Number of Connections

2 sets of 2 connections Screw Cage terminals 0.32 – 2.5 mm 2 / 22 – 14 AWG

Wire Strip Length

7 - 9 mm / 0.28 – 0.36 in.

Maximum Current

10 A max. at 250 VAC max. **

Color

Black

*Actual Current draw is determined by type of CHARM and associated field devices. **Actual Current draw through the Address Block Terminal Block is determined by the combined current draws through Injected-Power Terminal blocks on each CHARM Baseplate.

LS Analog Input 4-20 mA HART CHARM Specifications for LS AI 4-20 mA HART CHARM Sensor Types

4-20 mA with or without HART 0-20 mA Supports 2-wire and 4-wire device types directly Supports 3-wire device powered through the LS 24 VDC Power CHARM

Nominal Signal Range (Span)

4-20 mA, (0-20 mA optional)

Full Signal Range

0-24 mA

Input Impedance

250 ohms ±1%

Field Power (2-wire)

15.0 V at 20 mA @ 24 VDC input

Accuracy Over Temperature Range

0.1% of span (0 to 60°C) 0.25% of span (over -40 to 70°C)

Safety Accuracy

2% of span

Repeatability

0.05% of span

Resolution

16-bit A/D converter

Calibration

None required

DC/50/60 Hz Common Mode Rejection

N/A

Field Circuit Protection

–– ––

CHARM Power Req.

30 mA Current Limiting circuit Field wiring disconnect

32 mA max @ 24 VDC for two wire configuration 8 mA max @ 24 VDC for three and four wire configuration

Charm Heat Dissipation

0.33 Watts

HART Support

HART v7 pass-through for AMS HART v7 variable and device status available to control

HART Data Update Rates


Typically less than one second but dependent on HART communication loading and the capability of the HART device

23


October 2017

Simplified Circuit and Connection Diagrams for LS AI HART CHARM 0/ 4 to 20 mA Two Wire and Four Wire transmitters.

Simplified Circuit and Connection Diagrams for AI HART CHARM 0/ 4 to 20 mA with 3-wire AI Fused Injected Power Terminal Block.


24


October 2017

LS RTD Input CHARM Specifications for LS RTD CHARM Sensor Types

RTD input (Types listed in Table)

Sensor Configuration

2 wire, 3 wire, or 4 wire

Full Scale Signal Range

See Table below

Accuracy

See Table below

Repeatability

0.05% of span

Resolution

24 Bit A/D converter / Depends upon the sensor type

Calibration

None required

Sensor Excitation Current

0.5 mA in 2-wire and 4 wire configurations 0.25 mA in 3-wire


90dB

Isolation

Each sensor galvanically isolated and factory tested to 1000 VDC

Open Sensor Detection

Yes

CHARM Power Req.

18 mA max @ 24 VDC

CHARM Heat Dissipation

0.30 Watts

RTD, ohms Sensor Type Specifications Sensor Type

Operating Range

25°Reference Accuracy

Temperature Drift

Resolution

Pt100

-200 to 850°C

± 0.25°C

± 0.02°C/°C

~ 0.02°C

Pt200

-200 to 850°C

± 0.25°C

± 0.02°C/°C

~ 0.02°C

Pt500

-200 to 850°C

± 0.25°C

± 0.02°C/°C

~ 0.02°C

Pt1000

-200 to 260°C

± 0.25°C

± 0.02°C/°C

~ 0.01°C

Ni120

-80 to 260°C

± 0.15°C

± 0.01°C/°C

~ 0.01°C

Ni100

-80 to 260°C

± 0.20°C

± 0.01°C/°C

~ 0.01°C

Ni200

-80 to 260°C

± 0.20°C

± 0.01°C/°C

~ 0.01°C

Ni500

-80 to 260°C

± 0.20°C

± 0.01°C/°C

~ 0.01°C

Ni1000

-80to 140°C

± 0.20°C

± 0.01°C/°C

~ 0.01°C

Cu10

-200 to 260°C

± 0.25°C

± 0.02°C/°C

~ 0.01°C

Resistance/User Defined*

0 to 2,000 Ω

± 0.25 Ω

± 0.03 Ω/°C

~0.031 Ω

* The Callendar-Van Dusen linearization equation can be used with user defined Pt RTDs. Refer to Recommended I/O Practices in DeltaV Books online for usage information.


25


October 2017

Simplified Circuit and Connection Diagrams for LS RTD CHARM.


26


October 2017

LS Thermocouple/mV Input CHARM Specifications for LS Thermocouple/mV Input CHARM Sensor types: Thermocouple

B, E, J, K, N, R, S, T,

mV

Low level voltage source (±20 mV, ±50 mV, and ±100 mV)


See Table next page

Accuracy

See Table next page

Repeatability

0.05% of span

Resolution

24 Bit A/D converter / Depends upon the sensor type

Calibration

None required

Cold junction Compensation(CJC): Accuracy

± 1.0°C

Range

-40 to 85°C


90dB

Isolation

Each sensor galvanically isolated and factory tested to 1000 VDC

Open Sensor Detection

Yes

CHARM Power Req.

18 mA max @ 24 VDC


0.30 Watts

Sensor Type Specifications

1

Sensor Type

25° Reference Accuracy1

Temperature Drift

Nominal Resolution

Full Scale

Operating Range

B

± 0.8°C

± 0.06°C/°C

~ 0.024°C

0 to 1820°C

250 to 1820°C

E

± 0.4°C

± 0.03°C/°C

~ 0.018°C

-270 to 1000°C

-200 to 1000°C

J

± 0.6°C

± 0.04°C/°C

~ 0.022°C

-210 to 1200°C

-210 to 1200°C

K

± 0.4°C

± 0.03°C/°C

~ 0.025°C

-270 to 1372°C

-200 to 1372°C

N

± 0.6°C

± 0.04°C/°C

~ 0.024°C

-270 to 1300°C

-200 to 1300°C

R

± 0.8°C

± 0.05°C/°C

~ 0.028°C

-50 to 1768°C

-50 to 1768°C

S

± 0.8°C

± 0.05°C/°C

~ 0.028°C

-50 to 1768°C

-50 to 1768°C

T

± 0.5°C

± 0.02°C/°C

~ 0.01°C

-270 to 400°C

-250 to 400°C

± 100 mV

0.025 mV

± 0.002 mV/°C

~ 0.0031 mV

-100 to 100 mV

-100 to 100 mV

± 50 mV

0.020 mV

± 0.001 mV/°C

~ 0.0015 mV

-50 to 50 mV

-50 to 50 mV

± 20 mV

0.010 mV

± 0.0005 mV/°C

~ 0.0006 mV

-20 to 20 mV

-20 to 20 mV

Total error is made up of the 25 C reference accuracy value, plus the CJC accuracy value, plus the sensor accuracy value.


27


October 2017

Simplified Circuit and Connection Diagram for LS Thermocouple/mV CHARM with Thermocouple/mV Terminal Block.

LS Analog Input 0-10 VDC Isolated CHARM Specifications for LS AI 0-10 VDC Isolated CHARM Sensor Types

Voltage device


See Table below

Accuracy

See Table below

Input Impedance

10 MΩ

Repeatability

0.05% of span

Resolution

24 bit A/D converter / Refer to the following table

Calibration

None required

Common Mode Rejection

90dB at 50/60 Hz

Isolation

Input channel galvanically isolated and factory tested to 1000 VDC

CHARM Power Req.

18 mA max @ 24 VDC


0.40 Watts


28


October 2017

Isolated Input Voltage Sensor Type Specifications Sensor Type

Sensor Range

25° Reference Accuracy

Temperature Drift

Nominal Resolution

0 to 5 V

0 to 5 V

± 0.005 V

± 0.0005 V/°C

0.00008 V

0 to 10 V

0 to 10 V

± 0.010 V

± 0.001 V/°C

0.00015 V

1 to 5 V

1 to 5 V

± 0.005 V

± 0.0005 V/°C

0.00006 V

1V

-1 to +1 V

± 0.0025 V

± 0.0002 V/°C

0.00003 V

5V

-5 to +5 V

± 0.005 V

± 0.0005 V/°C

0.00015 V

10 V

-10 to +10 V

± 0.010 V

± 0.001 V/°C

0.00030 V

Simplified Circuit and Connection Diagram for LS AI 0-10 VDC Isolated CHARM. Note: Installing a 250 Ω range resistor across terminals 3 and 4 converts a 4-20 mA field signal to 1-5V input signal.


29


October 2017

LS Discrete Input NAMUR CHARM Specifications for LS DI NAMUR CHARM Sensor Types

NAMUR Sensors, Dry Contacts, Dry contact with end of line resistance

Detection Level for On

> 2.1 mA (<4 kΩ)

Detection Level for Off

< 1.2 mA (>9 kΩ)

Channel Impedance

1.5 KW (approximate)

Wetting Voltage

12 Volts (± 5%)

Fault detection capable with NAMUR sensor or with an optional field resistor pack* as shown on Option 2 in diagram below (Option 1 in diagram below is not fault detection capable)

Guaranteed short circuit: <100 Ω Guaranteed good status: 400 Ω to 40 kΩ Guaranteed open circuit: > 75 kΩ

Configurable Channel Types:

Discrete input

Dry contact or discrete state sensor changing <2 Hz


8 mA Current Limiting Circuit Field wiring disconnect

CHARM Power Req.

24 mA max @ 24 VDC


0.51 Watts

*VS6904 End of Line Resistance Module can be used for option 2, see DeltaV SIS Conditioning Components PDS for more info.

Simplified Circuit and Connection Diagram for LS DI NAMUR CHARM.


30


October 2017

LS Discrete Input 24 VDC low-side sense (dry contact) CHARM Specifications for LS DI 24 VDC low-side sense (dry contact) CHARM Sensor Types

24 VDC Dry Contacts


> 2.25 mA (<5.3 kΩ)


< 1.75 mA (>8.2 kΩ)

Channel Impedance

4.8 KW

Wetting Voltage

22.5Volts (± 5%), current limited to 12.5 mA nominal

Fault detection capable with an optional field resistor pack* as shown on Option 1 in diagram below (Without resistor pack fault detection is not possible)

Guaranteed short circuit: <100 Ω Guaranteed good status: 400 Ω to 40 kΩ Guaranteed open circuit: > 75 kΩ


Discrete input



12.5 mA Current Limiting Circuit Field wiring disconnect

CHARM Power Req.

18 mA max @ 24 VDC


0.33 Watts

*VS6904 End of Line Resistance Module can be used for option 1, see DeltaV SIS Conditioning Components PDS for more info.

Simplified Circuit and Connection Diagram for LS DI 24 VDC low-side sense CHARM.


31


October 2017

LS Discrete Input 24 VDC Isolated CHARM Specifications for LS DI 24 VDC Isolated CHARM Detection level for On

> 10 VDC

Detection level for Off

< 5 VDC

Wetting Current

6 mA @ 24 VDC

Input Impedance

4 KW (approximately)

Isolation

Galvanically isolated and factory tested to 1000 VDC


Discrete input


Dry contact or discrete state sensor changing <2 Hz –– ––

Recommend External Fuse at power source Field wiring disconnect

CHARM Power Req.

8 mA max @ 24 VDC


0.32 Watts

Simplified Circuit and Connection Diagrams for LS DI 24 VDC Isolated CHARM.

Simplified Circuit and Connection Diagrams for LS DI 24 VDC Isolated CHARM with 3-wire DI Fused Injected Power Terminal Block.


32


October 2017

LS 24 VDC Power CHARM Specifications for LS 24 VDC Power CHARM Device Type

24 VDC Power output


> 10 VDC


< 5 VDC

Isolation

Status read back circuitry is optically isolated and factory tested to 1000 VDC. Output power has no isolation from the injection point.


–– ––

2 Amp fuse located in Fused Injected Power Terminal Block Field wiring disconnect

CHARM Power Req.

8 mA max @ 24 VDC

Injected Power Req.

1.01 Amps max @ 24 VDC


0.32 Watts

Simplified Circuit and Connection Diagrams for LS 24 VDC Power CHARM with Fused Injected Power Terminal Block.


33


October 2017

Simplified Circuit and Connection Diagrams for LS 24 VDC Power CHARM with Fused Injected Power Terminal Block - powering 3-wire HART Transmitter connected to LS AI HART CHARM 0/ 4 to 20 mA.

Simplified Circuit and Connection Diagrams for LS 24 VDC Power CHARM with Fused Injected Power Terminal Block - powering 4-wire HART Transmitter connected to LS AI HART CHARM 0/ 4 to 20 mA.


34


October 2017

LS Discrete Output 24 VDC DTA CHARM Specifications for LS 24 VDC DTA CHARM Device Type

24 VDC Solenoid coils

ON-State Output rating

500 mA continuous @ 24 VDC. The power is derived from power supplied to the CHARMs Smart Logic Solver Carrier

ON-State Current Limit

Output inrush current limited to 580 mA

OFF-State Leakage Current

Line Fault Detection Levels

5 mA maximum with line fault enabled. 300 μA simplex with line fault disabled. 600 μA redundant with line fault disabled. Guaranteed Short Circuit: < 10 Ω Load Guaranteed Good Status: 56 Ω to 3.5 kΩ Load Guaranteed Open Circuit: > 20 kΩ Load

Line Fault Test Timing

200 μsec


– –


Field Power Common Shutoff Signal

Logic low removes field power like in de-energize to trip applications

CHARM Power Req.

41 mA max @ 24 VDC


1.3 W

Simplified Circuit and Connection Diagram for LS DO 24 VDC DTA CHARM.


35


October 2017

LS Discrete Output 24 VDC ETA CHARM Specifications for LS 24 VDC ETA CHARM Device Type





Output inrush current limited to 580 mA



5 mA maximum with line fault enabled. 300 μA simplex with line fault disabled. 600 μA redundant with line fault disabled. Guaranteed Short Circuit: < 10 Ω Load Guaranteed Good Status: 56 Ω to 3.5 kΩ Load Guaranteed Open Circuit: > 20 kΩ Load


200 μsec


– –




CHARM Power Req.

41 mA max @ 24 VDC


1.3 W

Simplified Circuit and Connection Diagram for LS DO 24 VDC ETA CHARM.


36


October 2017

LS DVC HART DTA CHARM Specifications for LS DVC HART DTA CHARM Device Type

Digital Valve Controller


4 to 20 mA, (0 to 20 mA option)

Full Signal Range

0 to 24 mA


2% of span (0 to 60°C) 5% of span (-40 to 70°C)

Resolution

12 bits

Calibration

None required

Available Field Power

20 mA at 15 VDC supply into 250 W min. to 600 W max. load


–– ––




CHARM Power Req.

56 mA max @ 24 VDC


1.03 W

HART Support




Simplified Circuit and Connection Diagram for LS DVC HART DTA CHARM with LS DVC Terminal Block.


37


October 2017

LS Discrete Output 24 VDC Redundant DTA CHARM Specifications for LS DO 24 VDC Redundant DTA CHARM Device Type





Output inrush current limited to 1.16 A


5 mA maximum


Guaranteed Short Circuit: < 10 Ω Load Guaranteed Good Status: 56 Ω to 3.5 kΩ Load Guaranteed Open Circuit: > 20 kΩ Load


200 μsec


–– ––

1.16 A Current Limiting Circuit Field wiring disconnect


Logic low removes field power from both partners like in de-energize to trip applications

CHARM power req.

82 mA max.(109 mA when used with Relay Terminal block) @ 24 VDC


2.6 W

Simplified Circuit and Connection Diagram for LS DO 24 VDC Redundant DTA CHARM with LS Redundant Terminal Block.


38


October 2017

Simplified Circuit and Connection Diagram for LS DO 24 VDC Redundant DTA CHARM with LS Redundant DTA Fused injected Power Terminal Block.

Simplified Circuit and Connection Diagram for LS DO 24 VDC Redundant DTA CHARM with LS Redundant DTA Relay Terminal Block.


39


October 2017

LS Discrete Output 24 VDC Redundant ETA CHARM Specifications for LS DO 24 VDC Redundant ETA CHARM Device Type





Output inrush current limited to 1.16 A


5 mA maximum.


Guaranteed Short Circuit: < 10 Ω Load Guaranteed Good Status: 56 Ω to 3.5 kΩ Load Guaranteed Open Circuit: > 20 kΩ Load


200 μsec


–– ––

1.16 A Current Limiting Circuit Field wiring disconnect



CHARM Power Req.

82 mA max.(109 mA when used with Relay Terminal block) @ 24 VDC


2.6 W

Simplified Circuit and Connection Diagram for LS DO 24 VDC Redundant ETA CHARM with LS Redundant Terminal Block.


40


October 2017

Simplified Circuit and Connection Diagram for LS DO 24 VDC Redundant ETA CHARM with LS Redundant ETA RelayTerminal Block.


41


October 2017

LS DVC HART Redundant DTA CHARM Specifications for LS DVC HART Redundant DTA CHARM Device Type

Digital Valve Controller


4 to 20 mA, (0 to 20 mA option)

Full Signal Range

0 to 24 mA


2% of span (0 to 60°C) 5% of span (-40 to 70°C)

Resolution

12 bits

Calibration

None required

Available Field Power

20 mA at 15 VDC supply into 250 W min. to 600 W max. load


–– ––




CHARM Power Req.

86 mA max @ 24 VDC


2.06 W

HART Support




Simplified Circuit and Connection Diagram for LS DVC HART DTA CHARM with LS Redundant DVC Terminal Block.


42


October 2017

LS Discrete Input 120 VAC Isolated CHARM Specifications for LS DI 120 VAC Isolated CHARM Detection Level for On

> 84 VAC


< 34 VAC

Wetting Current

2 mA at 120 VAC

Input Impedance


Maximum Input Voltage

130 VAC

Frequency

50/60 Hz

Isolation

Each channel is optically isolated from the system at 250 VAC

Configurable Channel Types: Discrete Input



–– ––


CHARM Power Req.

8 mA max @ 24 VDC


0.41 W

Simplified Circuit and Connection Diagrams for LS DI 120 VAC Isolated CHARM.

Simplified Circuit and Connection Diagrams for LS DI 120 VAC Isolated CHARM with 3-wire DI Fused Injected Power Terminal Block.


43


October 2017

LS Discrete Input 120V AC Isolated Plus CHARM Specifications for LS DI 120V AC Isolated Plus CHARM Detection Level for On

>84V AC


<34V AC

Wetting Current

10 mA at 120V AC

Input Impedance

12 KΩ (approximately)


130V AC

Frequency

50/60 Hz

Isolation

Each channel is optically isolated from the system at 250V AC


Discrete Input Pulse Count


Dry contact or discrete state sensor changing <2 Hz Pulse train 0.1 Hz to 10 Hz


CHARM Power Req.

12 mA max @ 24V DC


1.3 W

Simplified Circuit and Connection Diagrams for LS DI 120V AC Isolated Plus CHARM.

Simplified Circuit and Connection Diagrams for LS DI 120V AC Isolated Plus CHARM with 3-wire DI Fused-Injected-Power Terminal Block.


44


October 2017

LS Discrete Input 230 VAC Isolated CHARM Specifications for LS DI 230 VAC Isolated CHARM Detection Level for On

> 168 VAC


< 68 VAC

Wetting Current

1 mA at 230 VAC

Input Impedance



250 VAC

Frequency

50/60 Hz

Isolation

Each channel is optically isolated from the system at 250 VAC

Configurable Channel Types: Discrete Input



–– ––


CHARM Power Req.

8 mA max @ 24 VDC


0.40 W

Simplified Circuit and Connection Diagrams for LS DI 230 VAC Isolated CHARM.

Simplified Circuit and Connection Diagrams for LS DI 230 VAC Isolated CHARM with 3-wire DI Fused Injected Power Terminal Block.


45


October 2017

System Compatibility

Hazardous Area/Location

DeltaV SIS with Electronic Marshalling hardware requires:

DeltaV SIS with Electronic Marshalling can be installed and used based on the following Standards:

v12.3 DeltaV SIS or later software SZ Controllers

CHARMs Smart Logic Solvers (CSLS)

LS-CHARMs

DeltaV SIS Smart Switches

AC power filter/suppressor

FM (USA) Class I, Division 2, Groups A, B, C, D, T4

cFM (Canada) Class I, Division 2, Groups A, B, C, D, T4

ATEX II 3G Ex nA IIC T4 Gc II 3G Ex nA [nL] IIC T4 Gc II 3G Ex nA [ic] IIC T4 Gc II 3G Ex nA nC IIC T4 Gc

IEC-Ex II 3G Ex nA IIC T4 Gc II 3G Ex nA nL IIC T4 Gc II 3G Ex nA ic IIC T4 Gc II 3G Ex nA nC IIC T4 Gc

Certifications The following certifications are available for DeltaV SIS with Electronic Marshalling:

CE EMC- EN 61326-1

FM FM 3600 FM 3611

CSA

Regarding the Installation instructions please refer to the following Documents: Class 1 Division 2 Installation Instructions CHARM Subsystem 12P5401 Class 1 Division 2 Installation Instructions DeltaV S-series 12P5402 Zone 2 Installation Instructions CHARM Subsystem 12P5403 Zone 2 Installation Instructions DeltaV S-series 12P5404

CSA C22.2 No. 213-M1987 CSA C22.2 No. 61010-1

ATEX ATEX 94/9/EC EN60079-0 EN60079-15

IEC-Ex IEC60079-0 IEC60079-15

Marine Certifications IACS E10 ABS Certificate of Design Assessment DNV-GL Marine Certificate

Wurldtech SZ Controller Achilles Communications Certification Level 1 (v12.3) Achilles Communications Certification Level 2 (v.13.3.1)


46


October 2017

Additional Field Circuit Certification Information Class I Division II Non incendive

Zone 2 Ex nL Certified

Zone 2 Ex ic Certified

Zone 2 Ex nA Certified

LS DI NAMUR

4

4

4

4

LS DI 24 VDC low-side sense (dry contact)

4

4

4

4

LS DI 24 VDC Isolated

–

–

–

4

LS 24 VDC Power

–

–

–

4

LS AI 4-20 mA HART

4

4

4

4

LS RTD Input

4

4

4

4

LS Thermocouple/mV Input

4

4

4

4

LS AI 0-10 VDC Isolated

4

4

4

4

LS DO 24 VDC DTA

–

–

–

4

LS DO 24 VDC DTA Redundant

–

–

–

4

LS DO 24 VDC ETA

–

–

–

4

LS DO 24 VDC ETA Redundant

–

–

–

4

LS DVC HART DTA

4

4

4

4

LS DVC HART DTA Redundant

4

4

4

4


–

–

–

–

LS DI 120 VAC Isolated Plus

–

–

–

–


–

–

–

–

CHARM Type Description

– Stands for: Not Applicable;

4Stands for : Certification is in place; 8 Stands for: Waiting for Certification


47


October 2017

Additional Field Circuit Certification Information Class I Division II Non incendive

Zone 2 Ex nL Certified

Zone 2 Ex ic Certified

Zone 2 Ex nA Certified

LS Thermocouple/mV Input CHARM with Thermocouple/mV Terminal Block

4

4

4

4

LS 24 VDC Power CHARM with Fused injected Power Terminal Block

–

–

–

4

LS DVC HART DTA CHARM with DVC Terminal Block

4

4

4

4

LS Redundant DO 24 VDC DTA CHARMS with one LS Redundant Terminal Block

–

–

–

4

LS Redundant LS DO 24 VDC DTA CHARMS with one LS Redundant DTA Relay Terminal Block

–

–

–

4

LS Redundant LS DO 24 VDC DTA CHARMS with one LS Redundant DTA Relay Fused Injected Power Relay Terminal Block

–

–

–

4

LS Redundant LS DO 24 VDC ETA CHARMS with one LS Redundant Terminal Block

–

–

–

4

LS Redundant LS DO 24 VDC ETA CHARMS with one LS Redundant ETA Relay Terminal Block

–

–

–

4

LS Redundant LS DVC HART DTA CHARMS with one LS Redundant DVC Terminal Block

4

4

4

4

CHARMs and Terminal Block Assembly Description

– Stands for: Not Applicable;

4 Stands for : Certification is in place; 8 Stands for: Waiting for Certification


48


October 2017

Ordering Information SZ Controllers and CSLSs Description

Model Number

Redundant SZ Controller Assembly (vertical carrier) – Includes 2 SZ Controllers, SZ Controller Carrier, 2 Ethernet Isolation Ports for twisted copper, 2 Power Plugs

SS3001

Redundant SZ Controller Assembly (horizontal carrier) – Includes 2 SZ Controllers, Dual Universal Safety Carrier, 2 Ethernet Isolation Ports for twisted copper, 2 Power Plugs

SS3003

Redundant SZ Controller Assembly (keylock - vertical carrier) – Includes 2 SZ Controllers, SZ Controller Carrier, 2 Keylock Ethernet Isolation Ports for twisted copper, 2 Power Plugs

SS3002

Redundant SZ Controller Assembly (keylock - horizontal carrier) – Includes 2 SZ Controllers, Dual Universal Safety Carrier, 2 Keylock Ethernet Isolation Ports for twisted copper, 2 Power Plugs

SS3004

Redundant CSLS Assembly - Copper (Includes CSLS Carrier, 2 CSLSs, 2 Power Modules, 2 single Safety Network Ports for twisted copper, 2 Power Plugs)

SS6501T01

Redundant CSLS Carrier Assembly - Copper (Includes CSLS Carrier, 2 single Safety Network Ports for twisted copper, 2 Power Plugs)

SS6501T05

Redundant CSLS (Includes 2 CSLSs and 2 Power Modules)

SS6502

CSLS Baseplates Assembly Description

Model Number

CSLS Baseplate Assembly with Standard Term Blocks (includes Baseplate, Address Terminal Block with screw terminals, 12 Standard Terminal blocks, and Baseplate Identifier)

SS4601T07

CSLS Baseplate Assembly with 3-wire DI Fused Injected Field Power (includes Baseplate, Address Terminal Block with Screw Terminals, 12 3-wire DI Fused Injected Power Terminal Blocks, and Baseplate Identifier)

SS4601T09

CSLS Baseplate Assembly with Fused Injected Field Power (includes Baseplate, Address Terminal Block with Screw Terminals, 12 Fused Injected Power Terminal Blocks, and Baseplate Identifier)

SS4601T08

CSLS Baseplate Assembly with 3-wire AI Fused Injected Field Power (includes Baseplate, Address Terminal Block with Screw Terminals, 12 3-wire AI Fused Injected Power Terminal Blocks, and Baseplate Identifier)

SS4601T11

CSLS Baseplate Address Plugs Description

Model Number

CHARMs Addressing Plugs (includes Address Plugs 1 through 8)

SS4602

CHARMs Addressing Plugs (includes Address Plugs 1 through 4)

SS4613


49


October 2017

CSLS Baseplate Extenders, Terminators, & Cables Description

Model Number

CSLS Baseplate Terminator, Top (Male) (includes a Baseplate Identifier and a Baseplate Separation Wall)

SS4604T03

CSLS Baseplate Terminator, Bottom (Female) (includes a Baseplate Identifier and a Baseplate Separation Wall)

SS4604T04

CSLS Baseplate Extender with Cable Connectors, Top (Male) (includes a Baseplate Identifier and a Baseplate Separation Wall)

SS4603T05

CSLS Baseplate Extender with Cable Connectors, Bottom (Female) (includes a Baseplate Identifier and a Baseplate Separation Wall)

SS4603T06

CSLS Baseplate Cables (includes two 0.5 m cables)

SS4605T02

CSLS Baseplate Cables (includes two 1 m cables)

SS4605T03

CSLS Baseplate Cables (includes two 2 m cables)

SS4605T04

Each vertical DIN rail requires a DIN Rail stop to lock baseplates in position. Order VE4054DRS, which is a box of 5.

Low Voltage Instrumentation LS CHARMs (CHARM Quantities – Does NOT include Terminal Blocks) Description

Model Number

LS DI NAMUR CHARM

SS4301T01

LS DI 24 VDC low-side sense (dry contact) CHARM

SS4301T02

LS DI 24 VDC Isolated CHARM

SS4301T07

LS 24 VDC Power CHARM

SS4302T05

LS DO 24 VDC DTA CHARM

SS4302T01

LS DO 24 VDC DTA Redundant CHARM

SS4302T11

LS DO 24 VDC ETA CHARM

SS4302T02

LS DO 24 VDC ETA Redundant CHARM

SS4302T12

LS DVC HART DTA CHARM

SS4302T03

LS DVC HART DTA Redundant CHARM

SS4302T13

LS AI 4-20 mA HART CHARM

SS4303T01

LS Thermocouple/mV CHARM

SS4303T02

LS RTD CHARM

SS4303T03

LS AI 0-10 VDC Isolated CHARM

SS4303T04

High Voltage Instrumentation LS CHARMs (Single CHARM Quantities – Does NOT include Terminal Blocks) Description

Model Number

LS DI 120 VAC Isolated CHARM

SS4301T03

LS DI 120 VAC Isolated Plus CHARM

SS4301T05*

LS DI 230 VAC Isolated CHARM

SS4301T04

* The LS DI 120V AC Isolated Plus CHARM requires a HotFix to be used with DeltaV v12.3.1 and v13.3.1.


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October 2017

Ordering Information (Cont.) Low Voltage Instrumentation LS CHARMs and Terminal Block Assembly Description

Model Number

LS Thermocouple/mV Input Assembly (Includes one LS Thermocouple CHARM and one Thermocouple/mV Terminal Block)

SS4303T52

LS 24 VDC Power CHARM Assembly (Includes one LS 24 VDC Power CHARM and one Fused Injected Power Terminal Block)

SS4302T55

Redundant LS DO 24 VDC DTA Assembly (Includes two Redundant LS DO 24 VDC DTA CHARMS, and SS4302T51 one Redundant LS Terminal Block) Redundant LS DO 24 VDC DTA Relay Assembly (Includes two Redundant LS DO 24 VDC DTA CHARMS, and one Redundant LS DTA Relay Terminal Block)

SS4302T61

Redundant LS DO 24 VDC DTA Injected Power Relay Assembly (Includes two Redundant LS DO 24 VDC DTA CHARMS, and one Redundant LS DTA Fused Injected Power Relay Terminal Block)

SS4302T71

Redundant LS DO 24 VDC ETA Assembly (Includes two Redundant LS DO 24 VDC ETA CHARMS, and one Redundant LS Terminal Block)

SS4302T52

Redundant LS DO 24 VDC ETA Relay Assembly (Includes two Redundant LS DO 24 VDC ETA CHARMS, and one Redundant LS ETA Relay Terminal Block)

SS4302T62

LS DVC HART DTA Assembly (Includes one LS DVC HART DTA CHARM and one DVC Terminal Block)

SS4302T53

Redundant LS DVC HART DTA Assembly (Includes two Redundant LS DVC HART DTA CHARMS, and one Redundant DVC Terminal Block)

SS4302T63

Additional Ordering Information for Protection Cover and Terminal Blocks Protection Cover (fits all terminal blocks) Description

Model Number

CHARM Protection Cover; Package of 12

SS6103

Terminal Blocks Description

Model Number

Standard CHARM Terminal Block

SS4501

3-wire DI Fused Injected Power Terminal Block

SS4512

Fused injected Power Terminal Block

SS4502

Thermocouple/mV Terminal Block

SS4504

3-wire AI Fused Injected Power Terminal Block

SS4511

LS DVC Terminal Block

SS4505

LS Redundant Terminal Block

SS4506

LS Redundant DTA Fused Injected Power Relay Terminal Block

SS4507

LS Redundant DTA Relay Terminal Block

SS4508

LS Redundant ETA Relay Terminal Block

SS4509

LS Redundant DVC Terminal Block

SS4510


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October 2017

SZ and CSLS Spare part ordering Information SZ and CSLS Spare Parts Description

Model Number

Power Terminal Plug for SZ, CSLS and Dual Universal Safety Carrier

KJ4005X1-BF1

Ethernet Isolation Port; twisted copper; for SZ or Dual Universal Safety Carriers

KL1604X1-BA1

Keylock Ethernet Isolation Port; twisted copper; for SZ or Dual Universal Safety Carriers

KL1604X1-BB1

Power Module for CSLS Carriers

KL1501X1-BA1

Safety Network Ports twisted copper; for CSLS Carriers

KL1603X1-BA1

Set of 2 Replacement Keys for Keylock Switch on SZ, CSLS and Dual Universal Safety Carrier

SS6201

LS CHARM Labeling part ordering Information LS CHARM I/O Labeling Parts Description

Model Number

Channel Identifier Labels for CSLS Baseplates; Package of 8

SS4606T02

CSLS Charm Baseplate Identifier; Package of 9

SS4606T03

250V 2A Fuse for Fused Terminal Block; Box of 20

KJ4010X1-BC1

Prerequisites DeltaV SIS with Electronic Marshalling hardware requires DeltaV v12.3 or later software. Keylock Ethernet Isolation Port requires DeltaV SIS v14.3 or later software.

Emerson North America, Latin America: +1 800 833 8314 or +1 512 832 3774 Asia Pacific: +65 6777 8211 Europe, Middle East: +41 41 768 6111 www.emerson.com/deltavsis

©2017, Emerson. All rights reserved. The Emerson logo is a trademark and service mark of Emerson Electric Co. The DeltaV logo is a mark of one of the Emerson family of companies. All other marks are the property of their respective owners. The contents of this publication are presented for informational purposes only, and while every effort has been made to ensure their accuracy, they are not to be construed as warranties or guarantees, express or implied, regarding the products or services described herein or their use or applicability. All sales are governed by our terms and conditions, which are available on request. We reserve the right to modify or improve the designs or specifications of our products at any time without notice.

DeltaV SIS with Electronic Marshalling - Emerson

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